Mortality level and predictors in a rural Ethiopian population: Community based longitudinal study

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Study Justification:
– Mortality rates in low-income countries, where vital registration systems are absent, are not easily available.
– The recent economic growth of Ethiopia and large-scale healthcare investments make investigating mortality figures worthwhile.
– This study aims to provide valuable information on mortality levels and predictors in a rural Ethiopian population.
Highlights:
– The study used longitudinal health and demographic surveillance data collected over a three-year period.
– The crude mortality rate was found to be 4.04 per 1,000 person-years.
– Mortality significantly declined among children under five and 5-14 years old, but increased among those aged 65 years and above.
– Factors such as gender, rural population, altitude, and marital status were identified as predictors of mortality.
Recommendations:
– Further research is warranted to identify the causes of higher mortality rates in certain population groups.
– The study highlights the need for targeted interventions to reduce mortality in these high-risk groups.
Key Role Players:
– Researchers and scientists involved in conducting the study.
– The Ethiopian Science and Technology Agency, which provided ethical clearance.
– The Health Research Ethics Review Committee of Mekelle University, which granted ethical approval.
– Data collectors, field supervisors, and the research team involved in data collection and supervision.
Cost Items for Planning Recommendations:
– Training and recruitment of data collectors.
– Field supervision and coordination.
– Data analysis using STATA 11.
– Ethical clearance and approval processes.
– Communication and dissemination of study findings.
Please note that the provided information is based on the given description and may not include all details from the original study.

The strength of evidence for this abstract is 8 out of 10.
The evidence in the abstract is strong because it is based on a community-based longitudinal study with a large sample size. The study used data generated by the KA-HDSS, a longitudinal population-based surveillance system, which adds to the credibility of the findings. The study analyzed a substantial amount of person-years of observation and used statistical methods to identify predictors of mortality. The study also obtained ethical clearance and approval from relevant committees. To improve the evidence, the abstract could provide more details on the methodology, such as the specific statistical tests used and any potential limitations of the study.

Background: Over the last fifty years the world has seen enormous decline in mortality rates. However, in low-income countries, where vital registration systems are absent, mortality statistics are not easily available. The recent economic growth of Ethiopia and the parallel large scale healthcare investments make investigating mortality figures worthwhile. Methods: Longitudinal health and demographic surveillance data collected from September 11, 2009 to September 10, 2012 were analysed. We computed incidence of mortality, overall and stratified by background variables. Poisson regression was used to test for a linear trend in the standardized mortality rates. Cox-regression analysis was used to identify predictors of mortality. Households located at <2300 meter and ≥2300 meter altitude were defined to be midland and highland, respectively. Results: An open cohort, with a baseline population of 66,438 individuals, was followed for three years to generate 194,083 person-years of observation. The crude mortality rate was 4.04 (95% CI: 3.77, 4.34) per 1,000 person-years. During the follow-up period, incidence of mortality significantly declined among under five (P<0.001) and 5-14 years old (P<0.001), whereas it increased among 65 years and above (P<0.001). Adjusted for other covariates, mortality was higher in males (hazard ratio (HR) = 1.42, 95% CI: 1.22, 1.66), rural population (HR = 1.74, 95% CI: 1.32, 2.31), highland (HR = 1.20, 95% CI: 1.03, 1.40) and among those widowed (HR = 2.25, 95% CI: 1.81, 2.80) and divorced (HR = 1.80, 95% CI: 1.30, 2.48). Conclusions: Overall mortality rate was low. The level and patterns of mortality indicate changes in the epidemiology of major causes of death. Certain population groups had significantly higher mortality rates and further research is warranted to identify causes of higher mortality in those groups. © 2014 Weldearegawi et al.

This study used data generated by the KA-HDSS, which is a longitudinal population-based surveillance system. The KA-HDSS, member of the INDEPTH Network [14], is located about 802 km North of Addis Ababa, the capital of Ethiopia. Nine rural and one urban Kebele (smallest administrative unit in Ethiopia with average population of 5,000) were selected using the probability proportional to size technique (Figure 1). Agro-climatic condition, rural-urban composition, geographic location (highland and midland) and disease burden considerations were made during selection of study villages. The cohort was established with baseline data from 66,438 individuals living in 14,453 households. All households in the selected Kebeles and all individuals in these households were included in the follow-up that was done twice in a year through house-to-house visit. During each visit, vital event information on pregnancy status, birth, cause of death with verbal autopsy [15], marital status change, and migrations were collected. Full time data collectors, who at least completed high school, were recruited from the surveillance kebeles. They were trained for five days on data collection tools, interviewing techniques and ethical conduct of research using standard field manual. Besides, they were provided with refresher training biannually. The data collection process was supervised by field supervisors, a field coordinator and the research team. To link event histories, a permanent unique identification number (ID) was given for each individual and household that ever entered the cohort. To avoid incorrect attribution of data, household and individual ID were neither given to another individual or household nor changed over time. The surveillance employed standard data collection tools and procedures adopted from the INDEPTH Network [14]. Geographic location data were also collected at household level. Households located at <2300 meter and ≥2300 meter altitude were defined to be a midland and highland, respectively [16]. All study households had access to primary health care facilities (with in 5 km distance), that provide free maternal and child health services. At kebele level, there are two Health Extension Workers (HEWs) who are responsible for health promotion, prevention and treatment of common illnesses. The KA-HDSS uses the Household Registration System (HRS version 2.1) FoxPro database. Data analysis was done using STATA 11. Incidence of mortality was calculated by dividing number of deaths in a given group or time period by the total sum of person-time in the specific group or time period. Person-time of observation was determined as the difference between a subject's end date and start date of follow-up. The total person-time was split by year and age-category to calculate mortality rates by age and by year. Cox proportional hazards regression model were used to estimate hazard ratios and corresponding 95% confidence intervals. Poisson regression was used to test for a linear trend in the standardized mortality rates. This paper is based on three years surveillance data, from September 11, 2009 to September 10, 2012. The KA-HDSS received ethical clearance from the Ethiopian Science and Technology Agency with identification number IERC 0030. Ethical approval, with reference number ERC 0377/2014, was also obtained from the Health Research Ethics Review Committee (HRERC) of Mekelle University. To capture occurrence of vital events to any family member, head of a family or an eligible adult among the family was interviewed. Therefore, informed verbal consent was obtained from head of the family or eligible adult among the family, rather than each subject. This consent procedure was stated in the proposal which was approved by the ethical review committee. To keep confidentiality, data containing personal identifiers of subjects were not shared to third party.

Based on the information provided, it is difficult to determine specific innovations for improving access to maternal health. However, some potential recommendations could include:

1. Strengthening vital registration systems: Implementing systems to accurately record and track maternal health data, including pregnancies, births, and causes of death, can provide valuable information for monitoring and improving maternal health outcomes.

2. Enhancing community-based surveillance systems: Expanding and improving existing community-based surveillance systems, such as the KA-HDSS, can help identify and address barriers to accessing maternal health services in rural areas.

3. Increasing access to primary healthcare facilities: Ensuring that all study households have access to primary healthcare facilities within a reasonable distance can help improve access to maternal and child health services.

4. Strengthening the role of Health Extension Workers (HEWs): Providing additional training and support to HEWs, who are responsible for health promotion, prevention, and treatment of common illnesses, can help improve maternal health outcomes in rural communities.

5. Conducting further research: Identifying specific population groups with higher mortality rates and conducting further research to understand the causes of higher mortality in those groups can inform targeted interventions to improve maternal health outcomes.

It is important to note that these recommendations are general and may need to be tailored to the specific context and challenges faced in improving access to maternal health in rural Ethiopia.
AI Innovations Description
Based on the information provided, the recommendation to improve access to maternal health based on the study findings could be to implement targeted interventions in rural areas, particularly in highland regions, where the study identified higher mortality rates. These interventions could focus on improving access to maternal healthcare services, including antenatal care, skilled birth attendance, and postnatal care. Additionally, efforts should be made to address the specific needs of vulnerable populations, such as widowed or divorced individuals, who were found to have higher mortality rates. This could involve providing targeted support and resources to ensure their access to maternal healthcare services. Overall, the recommendation is to prioritize and invest in improving access to maternal health services in rural areas, with a particular focus on highland regions and vulnerable populations.
AI Innovations Methodology
Based on the information provided, it seems that the study focused on mortality rates in a rural Ethiopian population. However, there is no specific information about maternal health or access to maternal health services in the study description. Therefore, it is not possible to directly derive recommendations or a methodology to improve access to maternal health from this study.

To generate recommendations and simulate the impact of these recommendations on improving access to maternal health, you would need to conduct a separate study or review existing literature specifically focused on maternal health in Ethiopia. This study could include data collection on factors affecting access to maternal health services, such as distance to healthcare facilities, availability of skilled birth attendants, cultural beliefs and practices, and socioeconomic factors.

Once the data is collected, you can use various methodologies to simulate the impact of recommendations on improving access to maternal health. One possible methodology is a simulation model, where you input different scenarios or interventions and analyze their potential impact on access to maternal health. This could involve modeling the effects of increasing the number of healthcare facilities, training more skilled birth attendants, implementing community-based interventions, or improving transportation infrastructure.

The simulation model would consider factors such as population size, geographic distribution, healthcare infrastructure, and socioeconomic indicators to estimate the potential impact of each recommendation. The model could also incorporate data on maternal health outcomes, such as maternal mortality rates, to assess the effectiveness of the recommendations in improving health outcomes.

Overall, to generate recommendations and simulate the impact of these recommendations on improving access to maternal health, you would need to conduct a separate study focused specifically on maternal health in Ethiopia and use appropriate methodologies, such as simulation modeling, to analyze the potential impact of different interventions.

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